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  • We're used to thinking of particle accelerators as huge,

  • expensive instruments like the Large Hadron Collider at CERN.

  • These beamlines can either be circular or linear

  • and can be miles long.

  • But the particle accelerator of the future might look pretty different.

  • It's built into a microchip.

  • This groundbreaking miniature accelerator is just 30 micrometers long,

  • which is about the width of a hair on your head.

  • So how the heck does it work?

  • And how can it possibly be so small?

  • I mean, what is this, a particle accelerator for ants?!

  • Well, particle accelerators do just thatthey accelerate particles.

  • They take beams of charged particles, like electrons or protons or others,

  • and speed them up and focus those particles using magnetic and/or electric fields.

  • This beam of now super fast particles can hurtle through a vacuum in the accelerator

  • at nearly the speed of light until they crash into another beam of charged particles or a fixed target.

  • The resulting data can then help us understand more about the nature and behavior of subatomic particles,

  • which in turn can tell us a lot about chemistry,

  • biology, materials science...

  • basically, everything around us.

  • But an intrepid team out of Stanford and SLAC is the very first to have produced a functioning prototype

  • of a miniature particle accelerator on a silicon chip.

  • The researchers etched a nanoscale channel into their silicon chip

  • and sealed it in a vacuum

  • just like is necessary on a big accelerator.

  • They accelerated electrons along this channel using infrared laser pulses—100,000 pulses per second!

  • Granted, the electrons were accelerated only to a fraction of the speed that the big versions get up to,

  • but no big magnets or electric fields were required!

  • They used infrared light because it has a tiny wavelength: about one-tenth the length of a human hair.

  • That's why its energy could accelerate electrons within the 30-micrometer runway in the chip

  • a tiny wavelength for a tiny distance.

  • This design required some brand-new engineering on the team's part,

  • who actually worked backwards, starting with their end goal.

  • They knew what they wanted the light to do to the electrons, so they ran inverse design algorithms.

  • This helped them come up with the layout of the nanoscale structures within the chip

  • that would let them achieve their goal.

  • This reverse engineering technique produced something that not only works, but is also remarkably beautiful.

  • While it is just a prototype,

  • this microchip particle accelerator is part of a larger effort

  • called the Accelerator on a Chip International Program, or ACHIP.

  • Because as it turns out, scaling down accelerator technology is pretty important.

  • Our normal, huge particle accelerators have helped us develop the technologies we use

  • in radiation treatment for cancers, among many other medical applications.

  • So, although this prototype hasn't reached anything close to the accelerations we can achieve

  • on those bigger versions,

  • miniaturizing this tech could eventually have a big impact in medicine.

  • The team is already working to achieve higher particle accelerations

  • within a slightly larger microchip by the end of 2020.

  • One of the collaborators is even working on a development

  • that would take these high-energy electrons

  • and channel them into the human body.

  • This could focus treatment for something like a tumor to a much more precise area,

  • providing more effective medical care with less potentially harmful side effects.

  • The team compares the sizing down of particle accelerators to the changes

  • that computers have gone through since the days when a computer filled a huge room,

  • to being able to hold one in the palm of your hand.

  • Further development in this field could make accelerator technology

  • which is currently only available at precious few facilities

  • much more accessible to research teams around the world.

  • Imaginepocket particle accelerators, helping us probe the fundamentals of our universe.

  • What else do you think a micro-accelerator could help us do?

  • Let us know in the comments below and subscribe to Seeker for all of your particle physics news.

  • Check out this video here for more highly accelerated science

  • and as always, thanks for watching.

  • I'll see you next time!

We're used to thinking of particle accelerators as huge,

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B1 中級

微尺度粒子加速器如何改變我們的世界? (How Microscale Particle Accelerators Could Transform Our World)

  • 7 0
    林宜悉 發佈於 2021 年 01 月 14 日
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